TRANSESTERIFICATION OF PALM OIL WITH METHANOL
USING BARIUM OXIDE
MUHAMAD ZAHRUL BIN GHAZALI
Thesis submitted in fulfillment of the requirements
for the award of the degree of
Bachelor of Chemical and Natural Resources Engineering
Faculty of Chemical and Natural Resources Engineering
UNIVERSITI MALAYSIA PAHANG
JANUARY 2012
vi
ABSTRACT
Transesterification is a transformation of ester into biodiesel accelerated with catalysts.
Biodiesel or biofuel is a great solution in greenhouse problems emitted by petroleum diesel.
Unlike underground oil reserves, biofuels are a renewable resource since crop can always
grow and turn into fuel. Using Barium Oxide as solid catalyst is to counterpart problems by
homogenous catalyst which require more energy in washing process for separation which
lead to more waste. The present studies aimed to determine the conversion of methyl ester
produced and the optimum operation condition for the transesterification process. The
research study is done in a batch reactor system. Optimum operating condition is at 50°C
with molar ration of palm oil to methanol is 1:15 and with catalyst loading of 3 wt%. The
highest conversion of methyl esters from this optimum operating condition is 84.15%.
vii
ABSTRAK
Proses pengesteran ialah perubahan ester kepada biodiesel yang menggunakan pemangkin
untuk meningkatkan kadar tindak balas. Biodiesel atau bahan bakar biologi adalah satu jalan
penyelesaian kepada masalah rumah hijau yang disebabkan oleh minyak petroleum. Tidak
seperti simpanan minyak bawah tanah, biodiesel adalah sumber yang boleh dikitar semula
kerana penanaman semula boleh dilakukan dan ditukar menjadi biodiesel. Menggunakan
Barium Oksida sebagai pemangkin pepejal adalah untuk mengelak masalah yang ditimbulkan
oleh pemangkin yang larut dalam fasa yang sama di mana memerlukan lebih banyak tenaga
semasa proses pembasuhan untuk proses pemisahan. Kajian terkni tertumu kepada mencari
peratusan penghasilan Metil Ester dan keadaan optima atau ternaik untuk penghasilan melalui
proses pengesteran ini. Kajian ini dijalankan menggunakan sistem reaktor batch. Dari skop
kajian, dapat dibuktikan bahawa keadaan optima dapat dicapai pada suhu 50°C dengan
nisbah 1:15 molar minyak masak kepada metanol dan 3 wt% penggunaan pemangkin.
Peratusan penghasilan tertinggi metal ester melalui kaedah optima ini ialah sebanyak 84.15%.
viii
TABLE OF CONTENTS
Page
SUPERVISOR’S DECLARATION ii
STUDENT’S DECLARATION iii
ACKNOWLEDGEMENTS v
ABSTRACT vi
ABSTRAK vii
TABLE OF CONTENTS viii
LIST OF TABLES xi
LIST OF FIGURES xii
LIST OF ABBREVIATIONS xiv
LIST OF SYMBOLS xvi
CHAPTER 1 INTRODUCTION 1
1.1 Background of the Study 3
1.2 Problem Statement 6
1.3 Research Objectives 7
1.4 Scope of Research 7
1.5 Significance of Study 8
CHAPTER 2 LITERATURE REVIEW 9
2.1 Introduction 9
2.2 Transesterification 10
2.3 Metal Oxide Catalyst 12
2.4 Acidic Solid Catalyst 14
2.5 Acid Base Solid Catalyst 14
2.6 Enzymatic Catalyst 15
2.7 Raw Material 16
2.7.1 Soybean Oil 16
2.7.2 Rapeseed Oil 17
ix
2.7.3 Palm Oil 17
2.7.4 Camelina Oil 18
CHAPTER 3 METHODOLOGY 21
3.1 Introduction 21
3.2 Raw Material and Chemical Substances 22
3.2.1 Palm Oil 22
3.2.2 Methanol 23
3.2.3 Barium Oxide 25
3.3 Equipment and Apparatus 25
3.4 Experimental Procedure 27
3.5 Experimental Studies on the Effect of Difference Operating Parameters 28
3.6 Analytical Method 30
3.6.1 Procedure for Stock Standard 32
3.6.2 Procedure for Working Standard 32
3.6.3 Calibration Curve 33
CHAPTER 4 RESULTS AND DISCUSSIONS 36
4.1 Effect of Reaction Time 37
4.2 Effect of Molar Ratio of Palm Oil to Methanol 38
4.3 Effect of Concentration of Barium Oxide 43
4.4 Effect of Temperature 47
CHAPTER 5 CONCLUSION AND RECOMMENDATION 52
5.1 Conclusion 52
5.2 Recommendation 53
x
REFERENCES 54
APPENDICES 60
A Experimental Diagram 57
B Calculation of Methyl Ester Conversion 59
C Data of Methyl Ester Conversion 63
D Data from Gas Chromatography Analysis 77
xi
LIST OF TABLES
Table No. Title Page
2.1 Summary of the transesterification process using metal oxide catalyst 19
3.1 List of raw materials and chemical substances 22
3.2 Chemical properties of methanol 24
3.3 List of equipment and apparatus 25
3.4 Operating condition for 1st parameter 29
3.5 Operating condition for 2nd
parameter 29
3.6 Operating condition for 3rd
parameter 30
3.7 Gas Chromatography Flame Ionization Detector (FID) 31
3.8 Stock standards 32
3.9 Working standards 33
C.1 Effect at 60 minutes 63
C.2 Effect at 300 minutes 63
C.3 Final effect of reaction time 64
C.4 Effect of 1:6 molar ratio 64
C.5 Effect of 1:9 molar ratio 65
C.6 Effect of 1:15 molar ratio 67
C.7 Effect of 1 wt% 68
C.8 Effect of 2 wt% 69
C.9 Effect of 3 wt% 71
C.10 Effect at 40°C 72
C.11 Effect at 50°C 73
C.12 Effect at 60°C 75
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LIST OF FIGURES
Figure No. Title Page
2.1 Transesterification equation 11
3.1 Schematic diagram of a batch reactor system using water bath 26
3.2 Summary of experiment methodology 27
3.3 Standard calibration curve for methyl palmitate 34
3.4 Standard calibration curve for methyl linoleate 34
3.5 Standard calibration curve for methyl oleate 35
4.1 Effect of reaction for optimum time 37
4.2 Conversion profile for the study of effect of molar ratio1:6 with
temperature 50°C and catalyst weight 3 wt% of oil 39
4.3 Conversion profile for the study of effect of molar ratio1:9 with
temperature 50°C and catalyst weight 3 wt% of oil 39
4.4 Conversion profile for the study of effect of molar ratio1:15 with
temperature 50°C and catalyst weight 3 wt% of oil 40
4.5 Conversion profile for the study of effect of molar ratio1:6, 1:9 and 1:15 with
constant temperature 50°C and catalyst weight 3 wt% of oil 41
4.6 Conversion profile for the study of effect of weight catalyst 1 wt% of oil
with temperature 50°C and molar ratio of palm oil to methanol 1:15 44
4.7 Conversion profile for the study of effect of weight catalyst 2 wt% of oil
with temperature 50°C and molar ratio of palm oil to methanol 1:15 45
4.8 Conversion profile for the study of effect of weight catalyst 3 wt% of oil
with temperature 50°C and molar ratio of palm oil to methanol 1:15 45
4.9 Conversion profile for the study of effect of weight catalyst 1, 2 and
3 wt% of oil with constant temperature 50°C and molar ratio of
palm oil to methanol 1:15 46
4.10 Conversion profile for the study of effect of temperature at 40°C with
catalyst weight 3 wt% of oil and molar ratio of palm oil to methanol 1:15 48
4.11 Conversion profile for the study of effect of temperature at 50°C with
catalyst weight 3 wt% of oil and molar ratio of palm oil to methanol 1:15 49
4.12 Conversion profile for the study of effect of temperature at 60°C with
catalyst weight 3 wt% of oil and molar ratio of palm oil to methanol 1:15 49
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4.13 Conversion profile for the study of effect of temperature at
40°C, 50°C and 60°C with catalyst weight 3 wt% of oil and
molar ratio of palm oil to methanol 1:15 50
A.1 Experimental setup for batch reactor system 57
A.2 Samples taken after the reaction study 58
D.1 Data for sample 1 for effect of 1:6 molar ratio 77
D.2 Data for sample 2 for effect of 1:6 molar ratio 78
D.3 Data for sample 3 for effect of 1:6 molar ratio 79
D.4 Data for sample 1 for effect at 40°C 80
D.5 Data for sample 2 for effect at 40°C 81
D.6 Data for sample for effect at 40°C 82
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LIST OF ABBREVIATIONS
Al Aluminium
BaO Barium Oxide
CFAo Initial Concentration
CFA Final Concentration
CaO Calcium Oxide
CH3OH Methanol
CO2 Carbon Dioxide
CTAB Cetyltrimethyl Ammonium Bromide
DG Diglycerols
FFA Free Fatty Acid
FID Flame Ionization Detector
GC Gas Chromatography
H Hydrogen
ICP-AES Inductively Coupled Plasma Atomic Emission Spectroscopy
K/ZrO2 Tungstated Zirconium Dioxide
KOH Potassium Hydroxide
La2O3 Lathanium Oxide
MCM-41 Mobile Composition Matter-41
Mg Magnesium
MG Monoglycerols
MgO Magnesium Oxide
N2 Nitrogen
NaOH Sodium Hydroxide
O Oxygen
PPL Pig pancreatic Lipase
RML Rhizomucor miehei Lipase
SrO Strontium Oxide
T Temperature
TEOS Tetraethylorhosilicates
TG Triglyceride/Triacyglycerols
TiO2 Titanium Dioxide
W Weight
xv
XFA Conversion
ZnO Zinc Oxide
ZrO2 Zirconium Dioxide
xvi
LIST OF SYMBOLS
°C Degree Celcius
µg Micro Gram
µL Micro Liter
m Meter
kg Kilogram
wt Weight
mg Miligram
h Hour
min Minute
g Gram
µm Micrometer
rpm Revolutions per Minute
mL Mililiter
ppm Part per Million
m3 Meter cube
1
CHAPTER ONE
INTRODUCTION
Stringent environmental rules and legislation governing worldwide and recent
awakening to the realization of dismal scenario of fossil fuel availability have led to the
emergence of renewable fuels. The Malaysia National Biofuel Policy was launched on 21
March 2006 having envisions in use of environmentally friendly, sustainable and viable
sources of energy to reduce the dependency fossil fuel and enhanced prosperity and well-
being of all the stakeholders in the agriculture and commodity based industries through stable
and remunerative prices. A wide range of alternatives have been developed – from hydrogen
based vehicles to natural gas vehicle. However, one of them has been effective as biofuels –
ethanol and biodiesel – both from commercial as well as environmental perspective.
2
Feedstocks for biodiesel production vary considerably with location according to
climate and availability. Generally, the most abundant lipid in a particular region is the most
common feedstock. This, rapeseed oil is predominantly used in Europe, palm oil
predominates in tropical countries such as in Malaysia and soybean oil and animals fats are
primarily used in the United States. However, many of these oils are prohibitively expensive
and have competing food-related uses. Consequently, the development of alternative
feedstocks for biodiesel production that meet all or most of the following criteria has attracted
considerable research attention: high oil content, low agricultural inputs, favorable fatty acid
composition, compatibility with existing farm equipment and infrastructure, production in
sustainable fashion in off-season or in agriculturally undesirable lands, definable growth
seasons, and uniform seed maturation rates.
There are several feedstocks as raw material that can be used for the process of
biodiesel. Sugar cane as example, which is a major cultivation in Brazil. Brazil is the leader
in sugarcane ethanol fuel and the largest exporter of ethanol. Ethanol is to be the substitute
for gasoline for the main car fuel that can use around the globe. Then, there is also corn or
maize for the feedstock of biodiesel which is cultivated mostly in United States and Brazil. In
US, they had done an ethanol program and justified to eliminate additives on gasoline and
cutting down on global warming gases. Other than that, rapeseed or canola is also used as one
of the feedstock for biodiesel process. The major cultivation regions are EU, China, Canada
and India. In Europe, rapeseed ccounts for 80% of biofuel production. Even though this
plantation is not a food crop, the cultivation needs fertilizers and good soils. Palm oil also
used in biodiesel production which Indonesia and Malaysia is regions with a major
cultivation. Palm oil based biofuels provides a high quality fuel blend with fossil fuels such
as petroleum.
3
Global demand for edible oil is increasing in the few decades which cause a
tremendous increase in the area of oil crop cultivation especially soybean and oil palm. The
world production of palm oil is 45 million tones and highest production is in South East Asia
with a total 89% of total palm oil production (40% in Malaysia, 46% in Indonesia, 3% in
Thailand) (Shuit et al., 2009).
1.1 BACKGROUND OF THE STUDY
Biofuels have been around as long as cars have. At the start of the 20th
century, Henry
Ford planned to fuel his Model Ts with ethanol, and early diesel engines were shown to run
on peanut oil. But discoveries of huge petroleum deposits kept gasoline and diesel cheap for
decades, and biofuels were largely forgotten. However, with the recent rise in oil prices,
along with growing concern about global warming caused by carbon dioxide emissions,
biofuels have been regaining populariy. There are various ways of making biofuels, but they
generally use chemical reactions, fermentation, esterification, transesterification, and heat to
break down the starches, sugar, and other molecules in plants. The leftover products are then
refined to produce a fuel that cars can use. Countries around the world are using various
kinds of biofuels. For decades, Brazil has turned sugarcane into ethanol, and some cars there
can run on pure ethanol rather than as additive to fossil fuels.
From such facts, biofuels look like a great solution. Cars are a major source of
atmospheric carbon dioxide, the main greenhouse gas that causes global warming. But since
plants absorb carbon dioxide as comes out of the tailpipes of cars that burn these fuels. And
unlike underground oil reserves, biofuels are a renewable resource since we can always grow
more crops to turn into fuel.
The term biodiesel refers to the alkyl esters of fatty acids produced from vegetable oil,
animal fats and recycled greases when used as fuel for diesel engines. Biodiesel is most
commonly produced by the transesterification of acylglycerols with an alcohol, usually
methanol, in the presence of an alkaline catalyst. More recently, noncatalytic processes
utilizing supercritical alcohols have been employed.
4
When vegetable oils are used as the feedstock, three consecutive reactions give reise
to the formation of the fatty acid esters. The overall transesterification reaction proceeds as
equation below
Triglyceride + 3 R’OH <-> 3 R’COOR + Glycerol
On the basis of the above reaction, it is clear that one mole of triglyceride will yield
three moles of fatty acid esters and one mole of glycerol as a byproduct. The pure fatty acids
can then be used as a feedstock for biodiesel production.
Biodiesel is commonly derived from triglycerides and methanol through
transesterification using homogenous catalysts, such as alkali hydroxides (NaOH and KOH),
carbonates, and sodium and potassium alkoxides. The properties of biodiesel are similar to
those of petro-diesel fuels. The viscosity is the most valuable property of biodiesel fuels since
it has tremendous effects on the operation of fuel injection equipment, particularly at lower
temperature where an increase in viscosity affects the fluidity of the fuel. It was also
discovered that higher viscosity leads to poorer atomization of the fuel spray and which
affects accuracy of the operation of fuel injectors.
Biodegradability of biodiesel has been considered to be a solution for waste
accumulation leading to environmental pollution. Demirbas (2008) stated that biodegradable
fuels such as biodiesels have a wide range of potential applications and they are
environmentally friendly. The author revealed that there is growing interest in degradable
diesel fuels that degrade faster than the traditional disposable fuels. It was stated that
biodiesel is non-toxic and degrades about four times faster than petro-diesel. Also its oxygen
content improves the biodegradation process.
5
The use of millions of vehicle across the globe especially in big cities and towns
contribute a lot in generating gaseous emissions, hence polluting the environment. These
emissions referred to as green house gases are attributed to the cause of global warming.
Green house gases such as carbon-dioxide, carbon monoxide, nitrogen oxide, and sulfur
causes climatic distraction resulting in drought and environmental adversities and both fauna
and flora.
The application of biodiesel to our diesel engines for daily activities is advantageous
for its environmental friendliness over petro-diesel. The main advantageous of using
biodiesel is that it is biodegradable, can be used without modifying existing engines, and
produces less harmful gas emissions such as sulfur oxide. It can be concluded that the
advantages of biofuels over fossil fuels to be: (a) availability of renewable sources; (b)
representing CO2 cycle in combustion; (c) environmentally friendly; and (d) biodegradable
and sustainable. Other advantages of biodiesel are as follows: portability, ready availability,
lower sulfur and aromatic content, and high combustion characteristics.
6
1.2 PROBLEM STATEMENT
Despite the environmental advantage of the biodiesel, production cost of biodiesel is
pretty high compared to conventional diesel fuel. In order to reduce the production cost, used
vegetable oils has been suggested as feedstock. However the free fatty acids in used
vegetable oils are known to cause severe problems for the transesterification catalyzed by
base catalyst. Free fatty acids can react with the base catalyst (neutralization reaction), which
brings a loss of catalyst and a production of soap as by-product which accelerates the
deactivation of the base catalyst (Park et al., 2008).
The most widely used industrial method for the commercial production of biodiesel
from vegetable oils/fats is a base catalyzed transesterification process using KOH or NaOH
as the homogeneous catalyst and MeOH as the lower alcohol. The advantage of this process
is production of methyl esters at very high yields. Several oils, both edible and non-edible
such as sunflower oil, palm and jatropha have been transesterified for biodiesel production.
However, major quality related problems were encountered and it was main hindrance for
large scale industrial production of biodiesel by homogeneously catalyzed transesterification.
Biodiesel synthesis using solid catalysts instead of homogeneous liquid catalysts
could potentially lead to economical production cost because of reuse of the catalysts (Suppes
et al., 2004). Additional benefit with solid catalyst is the lesser consumption of catalyst.
Other than that, heterogeneous catalysts are solid and it can be separated from the product by
filtration, which reduces the washing requirement.
7
Chemistry of heterogeneous catalysts reported, includes metal hydroxides, metal
complexes, metal oxides such as calcium oxide, magnesium oxide, zeolites and supported
catalysts. These types of catalysts have been investigated as solid catalysts which overcome
some of the drawback on use of homogeneous catalysts.
In this study, heterogeneous solid catalysts, barium oxide are used to convert the raw
material into biodiesel. The raw materials used are palm oil and methanol.
1.3 RESEARCH OBJECTIVES
The objectives of this research are:
a) To determine the conversion of palm oil using barium oxide as catalyst.
b) To identify the optimum operating condition for the reaction.
1.4 SCOPE OF RESEARCH
The scope has been identified for this study in order to achieve the objectives. The
scopes of research are listed as below:
1. Study the effect of molar ratio of methanol to oil
2. Study the effect of concentration of barium oxide.
3. Study the effect of temperature.
8
1.5 SIGNIFICANCE OF STUDY
The rationales and significances of this study are:
1. Creating a new technology development for the production of biodiesel.
2. Utilized unrefined oils as raw material to produce high quality biodiesel.
3. Heterogeneous catalyst as environmental friendly due to less waste production
because the availability of reusing the catalyst.
9
CHAPTER TWO
LITERATURE REVIEW
2.1 INTRODUCTION
Doubtless, history will describe out time as the oil-based society. Nature took 500
million years to accumulate the world’s oil. A century ago the oil exploitation began, first as
a source of energy and now as a source both energy and raw material. Now, contemporary
society is highly dependent on the oil supply for energy, transportation, food production, and
in general, industrial production. Experts agree that the world’s petroleum will be consumed
in two centuries (Kerr, 1998). The inexorable production peak is estimated to occur sometime
between 2010 and 2020, and then the oil resources will be drastically reduced at the end of
this century (Campbell et al., 1998). Shortly after the production peak, the more expensive
fuel sources as hard-to-extract oil deposits, tarry sands, and synfuels from coal will be
brought to the front of production.
10
In addition to the expected development and implementation of new technologies for
conventional processes, such as cracking, hydrogenation, isomerization, alkylation, and
including transesterification and esterification. Biofuels, the renewable fuels are arguably one
of the best options to lead the transition away from petroleum fuels in the near-term and have
made a recent resurgence in response to rising oil prices. However, biofuels present resource
and environmental challenges depending on where, how, and from which feedstocks they are
developed.
2.2 TRANSESTERIFICATION
Transesterification is one of the classic organic reactions that have enjoyed numerous
laboratory uses and industrial applications. Organic chemists make use of this reaction quite
as a convenient means to prepared esters. On some occasions, transesterification is more
advantageous than the ester synthesis from carboxylic acids and alcohols. For instance, some
carboxylic acids are sparingly soluble in organic solvents and accordingly difficult to subject
to homogenous esterification whereas esters are commonly soluble in most of organic
solvents. The ester-to-ester transformation is particularly useful when the parent carboxylic
acids are labile and difficult to isolate. Some esters, especially methyl and ethyl esters, are
readily or commercially available and thus they serve conveniently as starting materials in
transesterification. This reaction can be conducted under anhydrous conditions to allow
employment of moisture-sensitive materials. Transesterification is applicable not only to the
pure organic synthesis but also to polymerization as example, ring opening of lactones.
Besides the laboratory utilization, transesterification has long history in industry as well.
Production of esters of oils and fats is very important and transesterification processes were
shown to have worked early in this century. Transesterification also plays a central role in the
paint industry such as curing of alkyd resins. In the middle of this century, the reaction
between dimethyl terephthalate and ethylene glycol became a crucial step for polyester
production although the process has almost been replaced by direct esterification of
terephtalic acid today.
11
Transesterification is a process where an ester is transformed into another through
interchange of the alkoxy moiety (Figure 2.1). Since the reaction is an equilibrium process,
the transformation occurs essentially by simply mixing the two components.
Figure 2.1: Transesterification equation
However, it has been known that the reaction is accelerated by acid or base catalysts.
Because of their versatility, the acid- or base- catalyzed reactions were the subjects of
extensive investigation, and the fundamental features were almost bought to light during
1950s and 1960s.
Rajesh et al., (2009) said that catalysis of the transesterification reaction can be
broadly classified into two categories-chemical and enzymatic. Chemically,
transesterification reaction can be acid/base catalyzed. The mixture of oil with excess of
ethanol when refluxed at 70oC for 1 h gave ethyl esters of fatty acids with a yield of 93%.
Though the yield is high, the process has many disadvantages such as high energy
consumption, difficulty in the transesterification of triglycerides with high free fatty acid
content.
12
Georgogianni et al. (2009) in comparisons of homogeneous and heterogeneous
catalysis in transesterification process said that homogeneous catalyst significantly
accelerated the transesterification reaction using both mechanical stirring and ultrasonication.
However, the use of homogeneous base catalysts requires neutralization and separation from
the reaction mixture leading to a series of environmental problems related to the use of high
amounts of solvents and energy. Heterogeneous solid base catalysts however can be easily
separated from the reaction mixture without the use of water, they are easily regenerated and
have a less corrosive nature, leading to safer, cheaper and more environment-friendly
operations.
2.3 METAL OXIDE CATALYST
Homogeneous catalyst are effective and feasible, but they lead to serious
contamination problems that make essential the implementation of good separation and
product purification protocols, resulting in increased production cost. To be economic and to
complete commercially with petroleum-based diesel fuel, processes for the synthesis of
biodiesel need to involve continuous processing in a flow system, have as few reaction steps
as possible, limit the number of separation processes, and ideally use the potential solid
catalyst for the heterogeneous transesterification reaction.
13
The catalyst efficiency depends on several factors such as specific area, pore size,
pore volume and active site concentration. The structure of metal oxides is made up of
positive metal ions (cations) which possess Lewis acidity, i.e. they behave as electron
acceptors, and negative oxygen ions (anions) which behave as proton acceptors and are thus
Bronsted bases. This has consequences for adsorption. In methanolysis of oils, it provides
sufficient adsorptive sites for methanol, in which the (O-H) bonds readily break into
methoxide anions and hydrogen cations. The methoxide anions then react with triglyceride
molecules to yield methyl esters (Chorkendorff and Niemantsverdriet, 2003). Liu et al.
(2008) found that small amounts of water can improve the catalytic activity of CaO and
biodiesel yields because in the presence of water, methoxide anions can be form from
extraction of H+ which will be the catalyst. However, if too much water (more than 2.8% by
weight of oil) is added to methanol, the fatty acid methyl ester will hydrolyze to generate
fatty acids, which can react with CaO to form soap. Dossin et al. (2006) showed that the
transesterification reaction occurs between the methanol molecules adsorbed on a magnesium
oxide. The methanol adsorption is assumed to be rate-determining step in catalysts such as
MgO and La2O3 while the surface reaction step becomes rate-determining with catalysts
having a higher basicity, such as BaO, CaO or SrO.
Calcium oxide is the metal oxide catalyst most frequently applied for biodiesel
synthesis, probably due to its cheap price, minor toxicity and high availability. It can be
synthesized from cheap sources like limestone and calcium hydroxide. Calsium oxide
possesses relatively high basic strength and less environmental impacts due to its low
solubility in methanol (Zabeti et al., 2009).